Báo cáo khoa học: A hydrophobic segment within the C-terminal domain is essential for both client-binding and dimer formation of the HSP90-family molecular chaperone pptx

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Báo cáo khoa học: A hydrophobic segment within the C-terminal domain is essential for both client-binding and dimer formation of the HSP90-family molecular chaperone pptx

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A hydrophobic segment within the C-terminal domain is essential for both client-binding and dimer formation of the HSP90-family molecular chaperone Shin-ichi Yamada 1,2 , Toshio Ono 2 , Akio Mizuno 1 and Takayuki K. Nemoto 2 1 Division of Oral and Maxillofacial Surgery and 2 Division of Oral Molecular Biology, Department of Developmental and Reconstructive Medicine, Course of Medical and Dental Sciences, Nagasaki University Graduate School of Biomedical Sciences, Japan The a isoform of human 90-kDa heat shock protein (HSP90a) is composed of three domains: the N-terminal (residues 1–400); middle (residues 401–615) and C-terminal (residues 621–732). The middle domain is simultaneously associated with the N- and C-terminal domains, and the interaction with the latter mediates the dimeric configuration of HSP90. Besides one in the N-terminal domain, an addi- tional client-binding site exists in the C-terminal domain of HSP90. The aim of the present study is to elucidate the regions within the C-terminal domain responsible for the bindings to the middle domain and to a client protein, and to define the relationship between the two functions. A bac- terial two-hybrid system revealed that residues 650–697 of HSP90a were essential for the binding to the middle domain. An almost identical region (residues 657–720) was required for the suppression of heat-induced aggregation of citrate synthase, a model client protein. Replacement of either Leu665-Leu666 or Leu671-Leu672 to Ser-Ser within the hydrophobic segment (residues 662–678) of the C-terminal domain caused the loss of bindings to both the middle domain and the client protein. The interaction between the middle and C-terminal domains was also found in human 94-kDa glucose-regulated protein. Moreover, Escherichia coli HtpG, a bacterial HSP90 homologue, formed hetero- dimeric complexes with HSP90a and the 94-kDa glucose- regulated protein through their middle-C-terminal domains. Taken together, it is concluded that the identical region including the hydrophobic segment of the C-terminal domain is essential for both the client binding and dimer formation of the HSP90-family molecular chaperone and that the dimeric configuration appears to be similar in the HSP90-family proteins. Keywords: GRP94; HtpG; molecular chaperone; dimer; client binding. The 90-kDa heat shock protein (HSP90) is a ubiquitously distributed molecular chaperone and is an essential protein in eukaryotic cells [1]. Most, if not all, compartments of mammalian cells contain specific members of HSP90. For instance, two HSP90 isoforms, HSP90a [2] and HSP90b [3], are present in the cytosol; the 94-kDa glucose-regulated protein (GRP94/gp96) is expressed in the lumen of endo- plasmic reticulum [4]; and TRAP1/hsp75 is expressed in mitochondria [5]. Also, HtpG exists in prokaryotic cells [6], although its expressionis not essential for the organisms [7,8]. HSP90 is either transiently or stably associated with specific client proteins that are unstable unless chaperoned with HSP90. Various regions of HSP90 have been proposed to be involved in the interactions with such target proteins. For instance, a highly charged region of chick HSP90 (amino acids 221–290) is essential for the binding to estrogen and mineralocorticoid receptors [9]; this region is also involved in the binding to the a subunit of casein kinase CK2 [10]. However, the corresponding highly charged region and C-terminal 35 residues that are specific to mammalian HSP90 can be deleted from yeast HSP82 [11]. Serial deletion experiments on HSP90b demonstrated that amino acids 327– 340, which are distinct but proximal to the charged region, are essential for chaperoning of serine/threonine kinase Akt/ PKB [12]. Two separate regions were proposed to be involved in the binding to the progesterone receptor [13]. At present, it is ambiguous whether this discrepancy is caused by the variation in the binding sites of HSP90 for the respective substrates or if the respective regions are respon- sible for certain aspects of the chaperoning mechanism. Another approach by use of model client proteins has been employed to clarify the client-binding sites of HSP90. By use of citrate synthase (CS) and insulin, it was observed that mammalian HSP90 possesses two distinct client- binding sites [14,15]: one of them is located in the N-terminal domain and its activity is modulated by ATP Correspondence to T. K. Nemoto, Division of Oral Molecular Biology, Nagasaki University School of Dentistry, 1-7-1, Sakamoto, Nagasaki 852-8588, Japan. Fax: + 81 95 849 7642, Tel.: + 81 95 849 7640, E-mail: tnemoto@net.nagasaki-u.ac.jp Abbreviations: HSP90, the 90-kDa heat shock protein; HSP90a and HSP90b,thea and b isoforms of HSP90, respectively; HtpG, an E. coli homologue of mammalian HSP90; GRP94, the 94-kDa glucose-regulated protein; GST, glutathione S-transferase; GST-HSP90a and H 6 HSP90a,HSP90a tagged with GST and a histidine hexamer (MRGSH 6 GS), respectively, at the N-terminus; CS, citrate synthase. (Received 19 August 2002, revised 12 November 2002, accepted 20 November 2002) Eur. J. Biochem. 270, 146–154 (2003) Ó FEBS 2003 doi:10.1046/j.1432-1033.2003.03375.x and geldanamycin, a specific inhibitor of HSP90 molecular chaperone; and the other is in the C-terminal domain. Minami et al. [16] and Tanaka et al. [17] confirmed the existence of these respective client-binding sites in the N- and C-terminal domains. Similarly, the C-terminal fragment (residues 494–782 as a mature form) of human GRP94 protects the catalytic subunit of protein kinase CK2 against thermal aggregation [18]. In contrast, we found a single client-binding site in Escherichia coli HtpG, which was localized solely in the N-terminal domain (residues 1–336) of the 624-amino acid protein [17]. All members of the HSP90 family proteins so far studied exist as dimers [19–22]. HSP90b analyzed by PAGE under nondenaturing conditions predominantly existed as a monomer [19]; it has been reported to exist as a dimers or as oligomers in rat liver cytosol, but tends to dissociate into monomers under the electrophoretic conditions [23]. Dis- ruption of the dimeric structure of HSP90 is lethal in yeast [24], although some of the monomeric mutants of HSP90 are able to confer viability and interact with the estrogen receptor [25]. The C-terminal 49 amino acids are essential for the dimer formation of HSP90 [24] and 191 amino acids are sufficient for the function [20]. We previously proposed on human HSP90a [20] and E. coli HtpG [26] that they form a dimer in an antiparallel fashion through a pair of the interactions between the middle domain and the C-terminal domain. Similarly, the C-terminal 326 amino acids of barley GRP94 [22] and 200 amino acids of canine GRP94 [27] are sufficient for the dimer formation. However, Wearsch and Nicchitta [27] proposed a distinct mechanism of dimer formation, on which the hydrophobic segment localized in the C-terminal domain interacts with each other. In the present study, we investigated two issues with respect to the C-terminal domain of HSP90. One was the identification of the minimal essential region required for the interaction with the middle domain, which mediates the dimerization of HSP90, and the other, the identification of the minimal region of the C-terminal domain for the client binding. Bearing in mind the fact that the 35-amino-acid residues corresponding to the C-terminus of HSP90 are deleted in HtpG, we postulated that the regions within the C-terminal domain responsible for dimerization, i.e. an interaction with the middle domain, and client binding, could be separated into the N- and C-terminal parts, respectively. However, the present study demonstrates that the two regions are unable to be separated and that the two functions are closely related to each other. We also reinvestigated the mode of dimer formation in the HSP90- family proteins. Experimental procedures Materials Expression vector pQE9 and plasmid pREP4 were pur- chased from Qiagen Inc. (Chatsworth, CA, USA) and expression vector pGEX4T-1, glutathione-Sepharose and low-molecular-mass markers, from Amersham Pharmacia Biotech (Uppsala, Sweden). Talon metal affinity resin was obtained from Clontech Laboratories Inc. (Palo Alto, CA, USA). Porcine heart CS was purchased from Roche Molecular Biochemicals (Mannheim, Germany). All other reagents were of analytical grade. Plasmid construction DNA fragments carrying truncated forms of human HSP90a amplified by PCR and cut with BamHI and SalI, were inserted into a BamHI/SalIsiteofpQE9(desig- nated pH 6 HSP90a). Construction of truncated forms of pH 6 HSP90a, i.e. pH 6 HSP90a542–732, 542–728, 542–720, 542–697 and 542–687 was described previously [28]. Trun- cated forms of HSP90a were also expressed as glutathione S-transferase (GST)-fusion proteins. The DNA fragments encoding HSP90a657–732, 676–732 and 697–732 were amplified by PCR and inserted into a BamHI/SalIsiteof pGEX-4T-1. Construction of the plasmid encoding amino acids 1–43/604–732 was described previously [28]. We also expressed the middle and C-terminal domains of human GRP94 as GST-fusion proteins. Although the domain structures and the domain boundaries of human GRP94 have not been determined, we tentatively defined the boundary between the N-terminal and middle domains to be Arg427-Glu428 and that between the middle and C-terminal domains to be Lys650-Asp651 by comparison with the amino acid sequence of human GRP94 [29] with those of human HSP90a [28] and E. coli HtpG [26]. Amino acid numbers refer to those of the mature form. Accord- ingly, the initial Met in the prepeptide corresponds to )21 and the mature form corresponds to Asp1–Leu782. The DNA fragments encoding the middle domain (Glu428– Lys650) and the C-terminal domain (Asp651–Leu782) of human GRP94 [29] were amplified by PCR and then inserted into a BamHI/SalI site of pGEX4T-1 (designated pGST-GRP94-M and pGST-GRP94-C, respectively). Y1090 cells transformed with these plasmids were selected on Luria broth agar containing 50 lgÆmL )1 of ampicillin. Constructed plasmids were verified by DNA sequencing. Expression and purification of recombinant proteins A histidine hexamer-tagged form of recombinant proteins was expressed and purified by use of Talon affinity resin according to the manufacturer’s protocol, except that 10 m M imidazole was added to the lysis/washing buffer. Bound proteins were eluted with 0.1 M imidazole (pH 8.0) containing 10% (v/v) glycerol. GST-fusion proteins were expressed and purified by binding to glutathione-Sepharose as described previously [30]. Bacterial two-hybrid system Bacterial strain BTH101 [F – , cya-99, araD139, gal15, galK16, rpsL1 (Strl r ), hsdR2, mcrA1, mcrB1] and plasmids pKT25 kan and pUT18C amp were provided by D. Ladant (Pasteur Institute, Paris, France) and L. Selig (Hybrigenics, S.A.,Paris,France).Animprovedversionofthebacterial two-hybrid system [31] was employed to evaluate domain– domain interactions of HSP90, GRP94 and HtpG. This method is based on the interaction-mediated reconstitution of an adenylate cyclase activity in the enzyme-deficient E. coli strain, BTH101. Because human HSP90a was proteolysed at Lys615-Ala616 and Arg620-Ala621 by Ó FEBS 2003 Two roles of the C-terminal domain of HSP90 (Eur. J. Biochem. 270) 147 trypsin [20,28], the border between the middle and C-terminal domains in the present study was set to Lys618-Leu619. The PCR fragment carrying the middle- C-terminal domains (residues 401–732) of HSP90a was inserted in a PstI/BamHI site of pUT18C amp . The DNA fragments carrying the C-terminal domain (residues 619– 732) of HSP90a or its truncated forms amplified by PCR were inserted into a PstI/BamHI site of pKT25 kan .The DNA fragments encoding tentative middle domain and C-terminal one of human GRP94 were amplified by PCR andtheninsertedinanXbaI/BamHI site of both pUT18C amp and pKT25 kan . The DNA fragment encoding the middle-C-terminal domains of GRP94 was amplified by PCR and then inserted in an XbaI/BamHI site of pUT18C amp . The construction of pKT25 kan -HtpG 337– 624/the middle-C-terminal domains was described previ- ously [17]. An E. coli strain BTH101 was cotransformed with pUT18C amp - and pKT25 kan -derived plasmids. The extent of reconstitution of the catalytic domains of Bordetella pertussis adenylate cyclase through the fused portions was quantified as b-galactosidase activity, which was measured after the bacteria had been cultured overnight at 30 °Cin Luria broth medium containing 50 lgÆmL )1 of ampicillin and 25 lgÆmL )1 kanamycin in the presence of 0.5 m M isopropyl thio-b- D -galactoside [31]. Suppression assay for heat-induced aggregation of CS Heat-induced aggregation of CS and its suppression in the presence of recombinant proteins were measured as des- cribed previously [32]. In brief, CS (8 lg) in the presence or absence of 6–48 lg of recombinant proteins in 0.4 mL of 40 m M Hepes, pH 7.4, was transferred at 45 °C. The absorbance at 360 nm was measured at 80 min, when the turbidity reached a plateau. SDS/PAGE PAGE was performed at a polyacrylamide concentration of 12.5% in the presence of 0.1% SDS. Separated proteins were stained with Coomassie Brilliant Blue. Low-molecular- mass markers (Amersham Pharmacia BioTech) were used as references. Protein concentration Protein concentrations were determined by the bicincho- ninic acid method (Pierce, Rockford, IL, USA). Results Minimal region of the C-terminal domain sufficient for dimerization with the middle domain The C-terminus of the C-terminal domain (Leu619– Asp732) of human HSP90a was serially truncated, and the binding activity to the middle domain (Glu401–Lys618) was quantified by using the bacterial two-hybrid system (Fig. 1). As reported previously on human HSP90a [17], because the C-terminal domain could not associate with the middle domain, but associated with the middle-C-terminal domains, we used the middle-C-terminal domains as a binding partner of the C-terminal domain in the two-hybrid system. As a result, H 6 HSP90a619–728, 619–720 and 619– 707 bound to the partner. Even H 6 HSP90a619–697 pos- sessed 72.5% of the maximal binding. However, truncation by additional 10 amino acids resulted in loss most of the binding. Thus, the C-terminal 35 amino acids of HSP90a were dispensable without significant loss of the dimer- forming activity, whereas further 10-amino acid truncation disrupted the function. In turn, the N-terminal side of the C-terminal domain was truncated. Residues 629–732 as well as 619–732 (the C-terminal domain) had the binding activity (Fig. 1). It should be noted that the full-length form of HSP90a was cleaved with chymotrypsin at Tyr627-Met628 and Met628- Ala629 bonds [20]. Thus, the Ala616-Met628 segment may not be essential for the function of the C-terminal domain. Hence, it was reasonable that residues 629–732 still retained the binding activity. The binding activity of residues 650– 732, i.e. a further deletion of the N-terminus up to Lys649, was 48.5% of the positive control (Fig. 1). Thus, residues 650–732 were essential for the binding, although its N-terminal proximal site (residues 629–649) may also be involved in the association. Minimal region sufficient for the binding to a model client protein Next, we measured the client-binding activity of the C-terminal site. We started from H 6 HSP90a542–732, an N-terminally histidine hexamer-tagged form, for the C-terminal truncation experiment (Fig. 2A). The truncated proteins were purified to near homogeneity (Fig. 2B, lanes 1–3 and lane 5) with an exception of GST-HSP90a 542–697 Fig. 1. Minimal region of the C-terminal domain that is required for the dimerization. The truncated forms of the C-terminal domain (residues 619–732) of human HSP90a were expressed in combination with the middle-C-terminal domains (resides 401–732). Residues 662–678 con- stitute the hydrophobic segment (see Fig. 3A). Residues 698–732 correspondtothedeletedregioninE. coli HtpG. The extent of the association was estimated by the b-galactosidase activity. The value of the combination of intact C-terminal domain (residues 619–732) with the middle-C-terminal domains was set to 100%. Values are means ± SD of three samples. 148 S i. Yamada et al. (Eur. J. Biochem. 270) Ó FEBS 2003 (lane 4). Aggregation of CS induced at 45 °Cwas suppressed in the presence of H 6 HSP90a542–732 in a dose-dependent manner. Its C-terminal truncation forms, i.e. H 6 HSP90a542–728 suppressed the CS aggregation (Fig.2C).H 6 HSP90a542–720 still suppressed the aggrega- tion, but the efficiency appeared to be lower than those of H 6 HSP90a542–732 and H 6 HSP90a542–728. A further truncated form, HSP90a542–687, showed no suppression. We could not test whether or not GST-HSP90a542–697 would suppress the aggregation of CS, because the prepar- ation contained doublet bands (Fig. 2B, lane 4) and self- aggregated at 45 °C even in the absence of CS (data not shown). We attempted to express even smaller fragments of N-terminal truncation than those of the C-terminal trunca- tions. However, recombinant proteins were not quantita- tively recovered in the expression system presumably due to the instability of exogenous proteins with small molecular masses in E. coli. Accordingly, the N-terminal-truncated forms were expressed as GST-fusion proteins with a relatively large moiety (Fig. 2A,B, lanes 6–9). As shown in Fig. 2D, GST-HSP90a1–43/604–732 and GST-HSP90 a657–732 suppressed the aggregation of the client protein. However, GST-HSP90a697–732 and GST-HSPa676–732, as well as GST, did not affect the process. Taken together, the data indicate that residues 657–720 are indispensable for Fig. 2. Suppression of the heat-induced aggregation of CS by the C-terminal regions of HSP90a. (A) HSP90a542–732 and its C-terminally truncated forms were expressed with an N-terminal histidine hexamer tag. HSP90a657–732, 676–732 and 697–732 were expressed as GST-fusion proteins. A dotted line indicates the boundary between the middle and C-terminal domains. (B) Purified proteins (1 lg) were electrophoresed on SDS/PAGE gels. Lane numbers are identical to those in Fig. 2A. M, low-molecular-mass markers. (C and D) The increase in the turbidity, representing the aggregation of CS, was measured after incubation with various concentrations of recombinant proteins at 45 °C for 80 min. Values are expressed as percents of the absorbance of CS in the absence of additional proteins (100%). (C) C- and (D) N-terminal truncation series. BSA, bovine serum albumin. Experiments (C and D) were repeated three times and essentially identical results were obtained. The data of one typical experiment are represented. Ó FEBS 2003 Two roles of the C-terminal domain of HSP90 (Eur. J. Biochem. 270) 149 the client-binding function. The activities of GST-fusion proteins were consistently higher than those of the histidine- tagged forms (compare Fig. 2C,D), which may be related to the dimeric nature of GST-fusion proteins as reported previously [33]. The dimeric form may more efficiently bind to a client protein like a clamp, as proposed for the mechanism of the action of the N-terminal domain of HSP90 [34–36]. Effect of amino acid replacements within the hydrophobic segment The above findings revealed an overlap or even identity between the region required for the dimer formation (residues 650–697) and that for the binding to a client protein (residues 657–720). Notably, a hydrophobic segment (residues 662–678) is located in the region (Fig. 3A). It is well known that high ionic strength does not induce the dissociation of an HSP90 dimer. Thereby, it is reasonable to postulate that the hydrophobic segment is involved in dimeric interaction, and presumably in client binding as well. In fact, Wearsch and Nicchitta [27] previously proposed that 45 amino acids carrying this hydrophobic segment were sufficient for the dimerization of GRP94. Hence, on the C-terminal domain of HSP90a, we substituted Leu665- Leu666 or Leu671-Leu672 located in this segment to Ser-Ser (Fig. 3A). As shown in Table 1, the C-terminal domain with either of these mutations completely lost its activity to bind to the middle-C-terminal domains. HSP90a657–732 with substitutions as represented in Fig. 3A was also expressed as GST-fusion proteins (Fig. 3B), and the suppression on CS aggregation at an elevated temperature was tested. The substitutions caused the loss of or a dose-dependent reduction in the suppression activity (Fig. 3C). Reinvestigation of the mode of dimer formation of GRP94 Because the C-terminal 326 residues of barley GRP94 [22] and 200 residues of canine GRP94 [27] are sufficient for the dimer formation, it is reasonable to postulate that the mode of the dimer formation is common among the HSP90- family proteins. However, it was reported that the 45 amino acids carrying the hydrophobic segment (see Fig. 3A) could self-dimerize when expressed as a fusion protein with a Table 1. Effect of amino acid substitutions in the hydrophobic segment in the C-terminal domain of HSP90a. The bacterial two-hybrid system was used to evaluate the binding activity. The binding activity of the C-terminal domain (100%) or its mutated forms toward the middle- C-terminal domains was quantified as the b-galactosidase activity of the bacterial two-hybrid system. Activities are given as mean ± SD (n ¼ 4). pKT25 kan - pUT18C amp - Activity (%) Vector Vector 6.5 ± 0.6 HSP90a-C HSP90a-MC 100.0 ± 0.8 HSP90a-C L665S/L666S HSP90a-MC 9.5 ± 0.4 HSP90a-C L671S/L672S HSP90a-MC 8.6 ± 2.4 Fig. 3. Effects of amino acid substitutions in the hydrophobic segment. (A) The amino acid sequences around the hydrophobic segment of 4 HSP90-family proteins are compared. Arrowheads indicate Leu-Leu replaced to Ser-Ser at amino acids 665 and 666 or at 671 and 672. Asterisks indicate identical amino acids. A bar represents the hydrophobic region (amino acids Leu662-Leu678 of human HSP90a). (B) SDS/PAGE of GST- HSP90a657–732 (lane 1), GST-HSP90a657– 732 L665S/L666S (lane 2), GST-HSP90a657– 732 L671S/L672S (lane 3) and GST (lane 4). M, low-molecular-mass markers. (C) The increase in the turbidity of CS (8 lg) with increasing amounts of recombinant proteins was measured as described in ÔExperimental ProceduresÕ. Experiments were repeated three times and identical results were obtained. The data of one typical experiment are represented. 150 S i. Yamada et al. (Eur. J. Biochem. 270) Ó FEBS 2003 maltose-binding protein [27]. This configuration of a GRP94 dimer is apparently distinct from our dimer model on HSP90, in which the middle domain is associated with the C-terminal domain in an antiparallel fashion [20,37]. It has also been reported that purified HSP90, GRP94 and HtpG self-oligomerize at elevated temperatures and that this phenomenon is closely related to the client-binding function of the proteins [32,38]. Taken together, we assumed that formation of the complex of the region carrying the hydrophobic segment of GRP94 is mediated via its client- binding activity. To settle this issue, we reinvestigated the domain–domain interaction of human GRP94 by use of the bacterial two-hybrid system. Table 2 shows that the dimerization was mediated via the interaction between the middle domain and the C-terminal one. Hence, we conclude that the C-terminal domain, which contains the hydrophobic region, does not associate with each other. Above findings let us further examine the possibility that hybrid dimers could be formed among three HSP90-family proteins. In a control experiment, the two-hybrid experi- ment demonstrated homodimer formation of the middle-C- terminal domains of HSP90a (Table 3). The two-hybrid experiment using the middle-C-terminal domains showed heterodimer formation between HSP90a and HtpG and between GRP94 and HtpG. On the other hand, a complex was not formed between HSP90a and GRP94 as reported previously [22]. We finally investigated whether the client-binding site of GRP94 is localized in either the middle domain or the C-terminal one. GRP94-M and GRP94-C were expressed as GST-fusion proteins. They were purified to near homo- geneity, although the preparation of GST-GRP94-M con- tained some amounts of 29-kDa GST species (Fig. 4A, lane 1). Figure 4B clearly demonstrated that GST-GRP94-C suppressed the aggregation of CS at 45 °C, but that GST- GRP94-M did not. Discussion Several biochemical properties and the roles have been characterized on the C-terminal domain of HSP90. At first, the C-terminal pentapeptide of HSP90 was recognized by the tetra-tricopeptide repeat (TPR)-domain containing cochaperone Hop, which connects HSP90 with the HSP70-family proteins [39]. Secondly, residues 702–716 adjacent to the C-terminus form one of the two most immunogenic regions [28], which strongly suggests that this region is exposed at the outer surface of an HSP90 dimer. Thirdly, the C-terminal 49 amino acids are essential for the dimer formation [24]. Fourthly, the C-terminal domain of HSP90 contains a client-binding site with characteristics distinct from those of the site located at the N-terminal domain [14–17]. This C-terminal client-binding site also exists in GRP94 [40], but not in HtpG [17]. However, the respective studies dealt with one of these properties, and Fig. 4. Suppression of the heat-induced aggregation of CS by the C-terminal domain of GRP94. (A) One microgram of GST-GRP94- M (lane 1), GST-GRP94-C (lane 2) and GST (lane 3) were electrophoresed on SDS/PAGE. M, low-molecular-mass markers. (B) The increase in the turbidity of CS (8 lg) with increasing amounts of GST-GRP94-M and GST-GRP94-C was measured. Experiments were repeated twice and identical results were obtained. The data of one typical experiment are represented. Table 3. Hybrid dimer formation in the C-terminal regions of 3 HSP90- family proteins. The bacterial two-hybrid system was used to evaluate the binding activity. The value of the combination of pKT25 kan - HSP90a-MC and pUT18C amp -HSP90a-MC was set to 100%. Activ- ities are given as mean ± SD (n ¼ 4). pKT25 kan - pUT18C amp - Activity (%) 1 Vector Vector 10.1 ± 0.2 HSP90a-MC HSP90a-MC 100.0 ± 1.3 GRP94-MC HSP90a-MC 13.9 ± 6.9 GRP94-MC HtpG-MC 81.2 ± 40.7 HSP90a-MC HtpG-MC 87.7 + 38.6 Table 2. Interaction between the middle and C-terminal domains of GRP94. The bacterial two-hybrid system was used to evaluate the binding activity. The value of the combination of the middle and the C-terminal domains was set to 100%. Activities are given as mean ± SD (n ¼ 3). pKT25 kan - pUT18C amp - Activity (%) vector vector 2.1 ± 0.4 GRP94-M GRP94-C 100.0 ± 0.7 GRP94-M GRP94-M 1.8 ± 0.5 GRP94-C GRP94-C 2.5 ± 0.2 Ó FEBS 2003 Two roles of the C-terminal domain of HSP90 (Eur. J. Biochem. 270) 151 therefore, it is still ambiguous whether the regions, especially the region responsible for dimer formation and that for client binding, exist at distinct sites of the C-terminal region, or they are closely related to each other. In our approach we initially focused on the C-terminal 35 amino acids of HSP90, of which the equivalent region is deleted in HtpG. Our hypothesis that the C-terminal 35 amino acids were not essential for the dimerization was verified by the data shown in Fig. 1. On the other hand, the second assumption that the 35 amino acids were involved in the client binding was not true, but the central part of the C-terminal domain, residues 657–720, was shown to be essential. Therefore, the two regions that were sufficient for both functions overlapped or were indistinguishable from each other. Their close relationship was ascertained by amino acid substitutions in the hydrophobic segment (Fig. 3 and Table 1). The present study demonstrated that, in HSP90a, double mutations of Leu to Ser at positions 665 and 666 or 671 and 672 in the hydrophobic segment diminished or completely destroyed the client-binding and dimer-forming activities simultaneously. The amino acid sequence of the hydropho- bic segment of HSP90a was relatively conserved with those of human GRP94 and E. coli HtpG (Fig. 3A). However, the difference was evident in the hydropathy plot of the C-terminal domain according to Kyte and Doolittle [41]. As shown in Fig. 5, the corresponding region of HtpG is less hydrophobic, which may explain the lack of the binding of the C-terminal domain of HtpG to a client protein [17]. We critically reviewed the previous study that demon- strated dimer formation of the hydrophobic segment of GRP94 [27]. The maltose-binding protein-fused GRP94 segment migrated with a wide range of apparent molecular masses on a size-exclusion chromatography column, indi- cating the formation of oligomers larger than a dimer. The present study on GRP94 demonstrated a direct interaction between the middle domain and the C-terminal one, and that neither the C-terminal domain nor the middle domain homo-dimerized. Accordingly, we propose that the dimeri- zation of the HSP90-family protein is generally achieved through a pair of heteromeric interactions between the middle and C-terminal domains. Self-oligomer formation of the hydrophobic segment of GRP94 [27] may reflect its potent client-binding capacity located in the C-terminal domain. The perfect dimer configuration of the HSP90-family protein seems to be accomplished through a pair of the intermolecular interactions between the middle and C-terminal domains as proposed previously [20], even if a single interaction between the middle and C-terminal domains might be sufficient to maintain the complex under the experimental conditions. Bearing in mind the finding that the hybrid formation of the N-terminal and middle domains between human HSP90a and E. coli HtpG [17], the conformational similarity of the HSP90-family proteins can be expanded to all domains of the protein. Bacterial two-hybrid experiments demonstrated the interaction between the middle and C-terminal domains of GRP94 (Table 2) as well as those of HtpG [17]. In contrast, the combination failed to form a complex in HSP90a [17], but the combination of the middle-C-terminal domains either with the middle domain or the C-terminal domain is required for the interaction (Fig. 1 and [17]). Presumably, the fine mode of the dimeric structure may be not identical among all members of the HSP90-family protein. Addi- tionally, it should be noted that this phenomenon made it difficult to reconstitute the complex between the middle and C-terminal domains with purified samples in vitro,because HSP90a-MC formed a stable dimer; neither the middle domain nor the C-terminal domain added afterwards was replaced (data not shown). Accordingly, an attempt to reconstitute such a complex of HSP90a in vitro was not successful (data not shown). The importance of the C-terminal region for the HSP90 molecular chaperone has been indicated by Sullivan and Toft [13]: two separate regions of chicken HSP90b (amino acids 381–441 and 601–677) are particularly important for the binding of the progesterone receptor. Hartson et al. [42] also proposed that a specific region near residue 600 determines the mode by which HSP90 interacts with substrates. Moreover, Glu651-Ile698 of human HSP90a, which carries the hydrophobic segment, is required for activation of basic helix-loop-helix-helix (bHLH) proteins, such as MyoD and E12 [43]. The findings in the present study on the client binding are consistent with these reports. Human GRP94 and mouse HSP90 were identified as tumor-specific antigens expressed on the surface of various tumor cells [44,45]. Recently, the C-terminal site of GRP94 bound to a vesicular stomatitis virus capsid-derived peptide was attributed to a charged region, Lys602-Asp-Lys-Ala- Leu-Lys-Asp-Lys609, by a photoaffinity labeling experi- ment [40]. This region is located in the middle domain (Glu428-Lys650), not in the C-terminal domain (Asp651- Leu782), in contrast to the results in the present study. At present, it remains unknown why this discrepancy occurred, but the dimer topology of the family proteins may provide a hint. That is, the middle domain associates with the Fig. 5. Hydropathy plot of the C-terminal domain of the 3 HSP90- family proteins. The hydropathy of the C-terminal domain of human HSP90a (light line), human GRP94 (dotted line) and E. coli HtpG (bold line) were plotted according to the methods of Kyte and Doo- little [41]. The amino acid numbers are represented as those of human HSP90a. 152 S i. Yamada et al. (Eur. J. Biochem. 270) Ó FEBS 2003 C-terminal domain in a GRP94 dimer, and accordingly, the charged region of the middle domain may be adjacent to the hydrophobic segment of domain C in the tertiary structure in a dimer. Therefore, it should be possible to confirm whether the Lys602-Lys609 charged region is truly indis- pensable for client binding or simply present adjacent to the client-binding site with the result of being affinity-labeled with the client peptide. This issue is now under investigation in our laboratory. Acknowledgements We greatly appreciate Drs D. Ladant (Pasteur Institute, Paris, France) and L. Selig (Hybrigenics S.A., Paris, France) for generous providing with the bacterial two-hybrid system. We also thank Mr T. Kobayakawa (Nagasaki University, Nagasaki, Japan) for the technical assistance. This work was supported by Grants-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science and Technology of Japan and from Japan Society for the Promotion of Science (to T. K. N.). References 1. Borkovich, K.A., Farrelly, F.W., Finkelstein, D.B., Taulien, J. & Lindquist, S. (1989) Hsp82 is an essential protein that is required in higher concentrations for growth of cells at higher temperatures. Mol. Cell. Biol. 9, 3919–3930. 2. Hickey,E.,Brandon,S.E.,Smale,G.,Lloyd,D.&Weber,L.A. (1989) Sequence and regulation of a gene encoding a human 89-kDa heat-shock protein. Mol. Cell. Biol. 9, 2615–2626. 3. Rebbe, N.F., Ware, J., Bertina, R.M., Modrich, P. & Sttafford, D.W. 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A hydrophobic segment within the C-terminal domain is essential for both client-binding and dimer formation of the HSP90-family molecular chaperone Shin-ichi. doi:10.1046/j.1432-1033.2003.03375.x and geldanamycin, a specific inhibitor of HSP90 molecular chaperone; and the other is in the C-terminal domain. Minami et al. [16] and Tanaka et al.

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